Seat Furniture, More Especially Office Swivel Chair

ABSTRACT

Seat furniture is provided that includes a seat and a backrest support which are mounted on a support member, the backrest support being pivotal about a horizontal pivot axis, and an energy accumulator which is tensioned when the seat is subjected to a load and acts on the backrest support, the energy accumulator engaging the backrest support at an effective distance from the pivot axis, characterized in that the energy accumulator is connected on one side to the support member and on another side via a transverse connector to the backrest support.

BACKGROUND OF THE INVENTION

The invention relates to seat furniture, more especially a swivel chairhaving an energy accumulator.

Such a chair is known for example from DE 198 23 632 C1. In this knownchair the energy or force accumulator is constructed in the form of atension spring which on the one side engages the backrest support. Inthe region of the front edge of the seat a two-armed lever is pivotallysecured to the support member, the one end of the two-armed lever beingpivotally connected to the seat and the other end of the two-armed leveris connected to the other end of the tension spring. By a load on theseat the two-armed lever is pivoted, the tension spring thereby beingtensioned and in turn biases the backrest support and the backrest inthe direction towards the front edge of the seat.

The mechanism described implements the feature that the pretensioning orbias of the backrest depends of the weight of the sitting person and itis therefore not necessary to adjust the pretensioning of the backrestto the weight of the user manually.

The disclosure is based on the problem of increasing the efficiency ofsuch a mechanism.

SUMMARY OF THE INVENTION

Briefly stated, seat furniture comprising a seat and a backrest supportwhich are mounted on a support member is pivotable about a horizontalpivot axis. An energy accumulator is tensioned when the seat issubjected to a load and acts on the backrest support. The energyaccumulator engages the backrest support at an effective distance fromthe pivot axis. The energy accumulator is connected on the one side tothe support and on the other side via a transverse connector to thebackrest support.

The energy accumulator is a tension spring in one embodiment. The energyaccumulator on the one side via a lever engages the backrest support andon the other side is connected via a transverse connector to thebackrest support. The energy accumulator may be a compression spring.The axis of the lever extends substantially parallel to the axis of thetransverse connector. The seat is articulately connected in a bearing tothe transverse connector between the connection to the energyaccumulator and the backrest support. The bearing is displaceable withrespect to the transverse connector.

The energy accumulator, in one embodiment, is connected to thetransverse connector via a deflection guide element. The bearing isarranged in the region of the rear half and preferably in the region ofthe rear third of the seat.

The seat may comprise an elastic cover which is clamped on the one sidein the support member and on the other side is connected to the backrestsupport. The elastic cover serves as an energy accumulator. The seat mayalso comprise a flexible cover connected on the one side to the energyaccumulator and on the other side to the backrest support. The effectivedistance at which the force accumulator engages the backrest support maybe variable.

The seat furniture utilizes the knowledge that the weight of a personsitting normally subjects the seat surface of the seat to the highestload in the rear region. Thus, in the described conventional mechanism,the weight force cannot be effectively utilized because in thismechanism the loading of the energy accumulator is over the front regionof the seat, which is the thigh region of the seated person.

In contrast, it is proposed that the energy accumulator engages thebackrest support via a transverse connector and can therefore bearranged in the rear region of the seat and can be actuated by almostthe full weight of the seated person.

The term “effective distance” here designates the effective leveragewith which the energy accumulator engages the backrest support for thepivoting thereof.

The seat is preferably pivotally connected to the transverse connectorby a mounting, this being done between the connection thereof with theenergy accumulator and the backrest support. On a loading of the seatthe transverse connector is pivoted at the backrest support and therebytensions the energy accumulator.

The extent of the pivoting of the transverse connector depends on theposition of the mounting on the transverse connector. If the mounting ismade movable with respect to the pivot point the magnitude of thetensioning of the energy accumulator and thus the bias of the backrestcan be adjusted.

It is not necessary here to connect the energy accumulator directly tothe transverse connector; this can also be done via a suitableconnecting element such as a chain, a cable or the like.

To enable the weight of the seated person to be utilized particularlyeffectively the mounting is arranged in the rear half, preferably in theregion of the rear third of the seat.

In an alternative solution of the problem the seat comprises an elasticcover which itself serves as energy person is utilized for tensioningthe energy accumulator.

This applies analogously in a further alternative in which a flexiblecover which is substantially not elastic is used as seat, the flexiblecover being connected to the energy accumulator in the form of a torsionrod, a torsion spring or a leg spring and on the other side to thebackrest or force accumulator, the elastic cover being clamped on theone hand on the support member and on the other hand connected to thebackrest support. This solution automatically fulfils the requirementthat substantially the entire weight of the seated support.

In all the embodiments the action of the energy accumulator on thebackrest support is dependent upon the effective distance between thepivot axis of the backrest support and the engagement point of theenergy accumulator. Accordingly, on changing the effective distance themagnitude of the biasing of the energy accumulator and thus themagnitude of the bias or pretensioning of the backrest can be varied.

Depending on the concrete configuration, it is possible to use as forceaccumulator for example tension springs, compression springs,gas-pressure elements, torsion springs, leg springs, etc.

BRIEF DESCRIPTION OF THE DRAWINGS

Examples of embodiments of the invention will be explained with the aidof the attached drawings. These show, in each case in side elevation:

FIG. 1, a chair according to a first embodiment;

FIG. 2, a detail view of a second embodiment;

FIG. 3, a third embodiment;

FIG. 4, a detail view of a fourth embodiment; and

FIG. 5 a detail view of a fifth embodiment.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

According to FIG. 1, the chair, in this case an office swivel chaircomprises in usual manner a roller cross 20 on which a chair column 22is connected to a support member 1. In a mounting 2 a backrest support 3is pivotally connected to the support member 1, the backrest support 3carrying a chair backrest 13.

The support member 1 further comprises a slide way 11 in which a linkguide 12 of a seat 5 is displaceably mounted.

In the front region of the support member 1 one end of a tension spring9 is pivotally mounted in a mounting 10, the other end of the tensionspring 9 being pivotally connected to a transverse connector 6 in abearing 8. The other end of the transverse connector 6 is mounted in abearing 4 of the backrest support. Via a lug 14 the transverse connector6 is pivotally connected in a bearing 7 to the seat.

When a person sits on the chair, due to the weight of the person thetransverse connector is pivoted via the lug 14 and the bearing 7 andtensions the tension spring 9, the tensioning of the tension spring 9depending on the weight of the person sitting down. On the other hand,by the tension of the tension spring 9 via the transverse connector 6the backrest support is biased, that is into the upright position of thebackrest 13. The seated person can pivot the backrest 13 rearwardly, theseat 5 being correspondingly displaced via the bearing 7 (to the rightin FIG. 1).

Since the pretensioning or biasing of the tension spring 9 and thus thebiasing of the backrest 13 is dependent on the weight of the personsitting down, manual adjustment is fundamentally not necessary.

On the other hand, steps can be taken to additionally adjust the biasingindividually manually. For this purpose for example the bearing 7 may bedisplaceably adjusted between the bearing 8 and the bearing 4, therebyenabling the pivot range of the transverse connector 6 to be varied. Itis also possible to vary the effective distance at which the energyaccumulator 9 engages the backrest support by for example providingmeans for varying the distance apart of the bearing 4 and 2. Theseadditional adjustment possibilities are not illustrated in FIG. 1.

FIG. 2 shows a detail of a second embodiment, identical parts beingdesignated with the same reference numerals.

In the second embodiment the tension spring 9 is not directly connectedto the transverse connector 6 but via a connecting element 15 in theform of a cable, chain or the like which is led over a deflection guidemember 10′. The one end of the tension spring is connected to the guideelement 15 and the other end is connected to a mounting 16 on thesupport member 1. The remaining constructional components correspond tothose of the first embodiment.

According to FIG. 3 the seat is formed as an elastic membrane 30 whichis fixedly clamped at 10″ on the support member 1 and is secured to thebackrest 13 at 4′. Due to its elasticity the membrane 30 effects thatunder the load of a seated person the backrest 13 is pretensioned,thereby achieving the same effect as in the first two examples ofembodiment.

The same effect is achieved in the example of embodiment illustrated inFIG. 4; in this case the seat is formed by a substantially non-elasticcover 32 which is connected at the support member 1 to an energyaccumulator 9′ in the form of a torsion rod, a torsion spring or a legspring. The cover is connected to the backrest 13 at 4′ corresponding tothe example of embodiment of FIG. 3.

FIG. 5 shows a detail view of a fifth embodiment, the same parts bearingthe same reference numerals. In contrast to the example of FIG. 1, inthis case the energy accumulator is a compression spring 34 which on oneside engages the transverse connector 6 and on the other side acts onthe backrest support 3 via a lever means 36. In the position illustratedthe lever 36 extends substantially parallel to the transverse connector6 and forms a rigid angle lever with the region of the backrest supportbetween the bearings 2 and 4. When the seat is subjected to a load thecompression spring 34, which is articulately connected to the anglelever in a bearing 38, is subjected to compressive stress so that aforce is transmitted to the lever 36 and thus to the backrest support 3such that the counter force of the backrest is proportional to the bodyweight.

In addition to the adjustment possibilities already mentioned in thepreceding embodiment, in this case there is the additional possibilityof configuring the bearing 38 to be displaceable along the axis of thelever 36 and thereby enabling the effective length of the lever 36 to bevaried, thus achieving a fundamental further possibility of adjustingthe counter force of the backrest.

In the above text the definitions of “front”, “rear”, etc. are derivedfrom the normal position of a chair.

It is furthermore to be noted that the backrest support and the backrestcan be made integrally with each other as illustrated for example inFIG. 3 or as separate parts in accordance with FIG. 1.

In all the embodiments, the chair is constructed above the chair columnsubstantially laterally symmetrically, and the mechanisms according toFIGS. 1 and 2 can be arranged centrally or doubled, one on each side.

It is furthermore clear that the devices and mechanisms described herecan also be employed in other seat furniture, such as 4-leg chairs,armchairs, sofas and the like, and the support member can becorrespondingly adapted as required.

1. Seat furniture comprising a seat and a backrest support which aremounted on a support member, the backrest support being pivotal about ahorizontal pivot axis, and an energy accumulator which is tensioned whenthe seat is subjected to a load and acts on the backrest support, theenergy accumulator engaging the backrest support at an effectivedistance from the pivot axis, characterized in that the energyaccumulator is connected on one side to the support member and onanother side via a transverse connector to the backrest support.
 2. Seatfurniture according to claim 1, wherein the energy accumulator is atension spring.
 3. Seat furniture according to claim 2, wherein thetransverse connector connects to the energy accumulator in a firstconnection and to the backrest support at a second connection and theseat is articulately connected in a bearing to the transverse connectorbetween the first connection and the second connection.
 4. Seatfurniture according to claim 2, wherein the energy accumulator isconnected to the transverse connector via a deflection guide element. 5.Seat furniture according to claim 1, wherein the transverse connectorconnects to the energy accumulator at a first connection and to thebackrest support at a second connection and the seat is articulatelyconnected in a bearing to the transverse connector between the firstconnection and the second connection.
 6. Seat furniture according toclaim 5, wherein the bearing is displaceable with respect to thetransverse connector.
 7. Seat furniture according to claim 5, whereinthe seat has a rear half region and the bearing is arranged in theregion of the rear half region of the seat.
 8. Seat furniture accordingto claim 7, wherein the seat has a rear third region and the bearing isarranged in the rear third region of the seat.
 9. Seat furnitureaccording to claim 1, wherein the energy accumulator is connected to thetransverse connector via a deflection guide element.
 10. Seat furnitureaccording to claim 1, wherein the effective distance at which the forceaccumulator engages the backrest support is variable.
 11. Seat furniturecomprising a seat and a backrest support which are mounted on a supportmember, the backrest support being pivotal about a horizontal pivotaxis, and an energy accumulator which is tensioned when the seat issubjected to a load and acts on the backrest support, the energyaccumulator engaging the backrest support at an effective distance fromthe pivot axis, characterized in that the seat comprises an elasticcover which is clamped on one side in the support member and on anotherside is connected to the backrest support, the elastic cover serving asenergy accumulator.
 12. Seat furniture comprising a seat and a backrestsupport which are mounted on a support member, the backrest supportbeing pivotal about a horizontal pivot axis, and an energy accumulatorwhich is tensioned when the seat is subjected to a load and acts on thebackrest support, the energy accumulator engaging the backrest supportat an effective distance from the pivot axis, characterized in that theseat comprises a flexible cover which is connected on one side to theenergy accumulator and on another side to the backrest support.